JP2013242276A - Data management system, radiation dose data management system, and radiation dose data communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely acquire and manage monitoring object data such as radiation dose, even when blackout occurs.SOLUTION: A radiation dose data management system 11 comprises: a data acquisition device 13 for acquiring radiation dose data; and a data management device 15 for managing time transition of the radiation dose data acquired by the data acquisition device 13. The data acquisition device 13 comprises: a radiation dose measurement unit 17 for measuring the radiation dose data; a storage unit 27 for storing the radiation dose data and identification information that is unique to the data acquisition device 13; a satellite communication unit 19 for transmitting the radiation dose data stored in the storage unit 27 and the identification information to the data management device 15; a control unit 29 for controlling operation of respective units including the radiation dose measurement unit 17, the storage unit 27, and the satellite communication unit 19; and a storage battery 25 for supplying electric power to the respective units so as to cause the control unit 29 to perform the operation.

Description

  The present invention relates to a data management system, a radiation dose data management system, and a radiation dose data communication method used when managing time transition of monitoring target data such as a radiation dose.

  Natural disasters suddenly hit and cause tremendous damage. In the Great East Japan Earthquake that occurred on March 11, 2011, the earthquake and the accompanying tsunami hit the TEPCO Fukushima Daiichi NPS. As a result of the widespread release of radioactive materials by this accident, high radiation dose spots (hot spots) were found in various places. For this reason, there is a concern that the impact on the living sphere by the scattered radioactive material may be prolonged.

  Patent Document 1 is known as a technique for managing the time transition of radiation dose data in a radiation management area. Patent Document 1 simultaneously captures radiation dose data measured by a dosimeter and image data of an installation area of the dosimeter imaged by a CCD camera, wirelessly transmitted to a data management apparatus provided at a remote location, and stored. By doing so, a radiation monitor system is described that enables appropriate and rapid exposure management.

JP 2004-12197 A

  However, in the system according to Patent Document 1, the operating state is maintained on the assumption that commercial power is supplied to the measurement point of radiation dose data. For this reason, in the system according to Patent Document 1, if a power failure occurs, the system cannot be maintained in an operating state. As a result, there has been a problem that radiation dose data cannot be acquired and managed together.

  The present invention has been made in view of the above circumstances, and provides a data management system capable of reliably acquiring and managing monitoring target data such as radiation dose even when a power failure occurs. With the goal.

  Another object of the present invention is to provide a radiation dose data management system and a radiation dose data communication method capable of reliably obtaining and managing radiation dose data even when a power failure occurs.

  A data management system according to the present invention includes a data acquisition device that acquires monitoring target data, and a data management device that manages a time transition of the monitoring target data acquired by the data acquisition device. The data acquisition device includes a measurement unit that measures monitoring target data, a storage unit that stores monitoring target data measured by the measurement unit and identification information unique to the data acquisition device, and the storage unit that stores the identification information. An acquisition-side communication unit that transmits monitoring target data and the identification information to the data management device; a control unit that controls operations of the measurement unit, the storage unit, and the acquisition-side communication unit; and the control And a storage battery that supplies power for causing the unit to perform the operation. The data management apparatus includes: a management communication unit that receives the monitoring target data and the identification information transmitted from the acquisition communication unit; and the monitoring target data and the identification information received by the management communication unit. And a management unit that manages the data acquisition apparatus in association with the data acquisition apparatus.

According to the present invention, even when a power failure occurs, acquisition and management of monitoring target data such as radiation dose can be reliably performed.
Problems, configurations, and operational effects other than those described above will be clarified by the following description of embodiments.

It is a whole lineblock diagram showing the outline of the radiation dose data management system concerning the embodiment of the present invention. It is an appearance perspective view of a data acquisition device which is a component of a radiation dose data management system concerning an embodiment of the present invention. It is a two-dimensional table which shows an example of radiation dose DB which the data management apparatus which is a component of the radiation dose data management system which concerns on embodiment of this invention has. It is process drawing showing the flow of a process between the data acquisition apparatus which comprises the data management system which concerns on embodiment of this invention, and a data management apparatus. It is a figure showing the time transition of the power consumption according to the displacement of the operation state of a data acquisition apparatus.

  Hereinafter, a data management system, a radiation dose data management system, and a radiation dose data communication method according to the present invention will be described in detail with reference to the drawings.

[Outline of Radiation Dose Data Management System 11 According to Embodiment of the Present Invention]
First, an outline of a radiation dose data management system 11 which is an embodiment of a data management system according to the present invention will be described with reference to FIGS. 1A and 1B. FIG. 1A is an overall configuration diagram showing an outline of a radiation dose data management system 11 according to an embodiment of the present invention. FIG. 1B is an external perspective view of a data acquisition device 13-1 that is a component of the radiation dose data management system 11 according to the embodiment of the present invention.

  The radiation dose data management system 11 according to the embodiment of the present invention corresponds to a subordinate concept of the data management system according to the present invention. The difference between the data management system according to the present invention and the radiation dose data management system 11 according to the embodiment of the present invention is the type of monitoring target data. More specifically, in the data management system according to the present invention, in addition to radiation dose data, meteorological data (for example, weather, temperature, barometric pressure, humidity, wind direction, wind power, rainfall, snowfall, solar radiation) as monitoring target data. In the radiation dose data management system 11 according to the embodiment of the present invention, radiation dose data is targeted as monitoring target data.

As shown in FIG. 1A, the radiation dose data management system 11 according to the embodiment of the present invention includes a plurality of data acquisition devices 13-1, 13-2,..., 13-n (where n is an arbitrary natural number). ) And one data management device (may be plural).
The plurality of data acquisition devices 13-1, 13-2,..., 13-n and one data management device 15 are configured as portable devices.

  The plurality of data acquisition devices 13-1, 13-2,..., 13-n have the same configuration. Therefore, by describing the configuration of the data acquisition device 13-1, the description will be replaced with the description of the configuration of the plurality of data acquisition devices 13-1, 13-2, ..., 13-n. In the following description, the plurality of data acquisition devices 13-1, 13-2,..., 13-n may be collectively referred to as “data acquisition device 13”.

  As shown in FIGS. 1A and 1B, the data acquisition device 13-1 includes a radiation dose measurement unit 17, a satellite communication unit 19, a GPS receiver 21, a solar power generation panel 23, a storage battery 25, a storage unit 27, and a control. A portion 29 is provided. As shown in FIG. 1B, the storage battery 25, the storage unit 27, and the control unit 29 are accommodated in a case 30 having a substantially rectangular parallelepiped shape. The radiation dose measurement unit 17, the satellite communication unit 19, the GPS receiver 21, and the solar power generation panel 23 are provided so as to be exposed outside the case 30.

  For example, the data acquisition device 13-1 is provided outdoors such as an area where the radiation dose is assumed to be high, a teaching area, a residential area, a mountain area, and the sea. Therefore, the case 30 has a robust structure having waterproofness, dustproofness, corrosion resistance, weather resistance, and impact resistance. The radiation dose measurement unit 17, the satellite communication unit 19, the GPS receiver 21, and the photovoltaic power generation panel 23 that are provided so as to be exposed outside the case 30 are also waterproof, dustproof, corrosion-resistant, and weather-proof similar to the case 30. A robust structure is used in consideration of safety and impact resistance.

  As shown in FIG. 1B, the radiation dose measurement unit 17 corresponding to the measurement unit of the present invention includes a plurality of radiation dosimeters 17a, 17b, and 17c that measure the radiation dose. The plurality of radiation dosimeters 17a, 17b, and 17c are provided at different height positions with respect to the ground surface. Specifically, for example, the radiation dosimeter 17a is provided at a height of approximately 5 cm, the radiation dosimeter 17b is approximately 50 cm, and the radiation dosimeter 17c is provided at a height of approximately 100 cm with respect to the ground surface.

As the radiation dosimeters 17a, 17b, and 17c, for example, a GM survey meter or a NaI scintillation survey meter may be employed. However, when measuring the radiation dose in the high radiation dose area, an appropriate measurement instrument other than the above may be used.
In the radiation dosimeters 17a, 17b, and 17c, a change in the detection sensitivity due to the measurement environment and a deviation of the indicated value due to the influence of component deterioration occur. In order to correct such a change in detection sensitivity and a deviation of the indicated value, the radiation dosimeters 17a, 17b, and 17c are used which are ensured by calibration periodically (for example, about once a year).

  When different radiation dosimeters are employed between the plurality of data acquisition devices 13-1, 13-2,..., 13-n, measurement data reading errors occur for each model and measurement system. Therefore, in order to eliminate such a reading error, the radiation dose data can be compared side by side (with a common accuracy) by applying a correction coefficient determined by examining the measurement instrument to be used in advance.

  The actual measurement result relating to the radiation dose obtained by the radiation dose measurement unit 17 is sent to the control unit 29. The control unit 29 converts the actual measurement result related to the radiation dose into a numerical value (equivalent dose) serving as an index representing the magnitude of the influence on the human body. The numerical value (measured value) converted in this way is handled as radiation dose data in the radiation dose data management system 11 according to the embodiment of the present invention.

  The satellite communication unit 19 corresponding to the acquisition-side communication unit of the present invention has a function of performing communication with the data management apparatus 15 serving as a communication partner using a satellite communication line 31 via an artificial satellite.

  The GPS receiver 21 has a function of receiving satellite radio waves transmitted from an artificial satellite for GPS (Global Positioning System) and outputting current position data of the data acquisition device 13-1.

  The photovoltaic power generation panel 23 having the function of the photovoltaic power generation unit of the present invention has a function of outputting DC power by photovoltaic power generation. The photovoltaic power generation panel 23 is provided on the top plate portion of the case 30 as shown in FIG. 1B. The photovoltaic power generation panel 23 employs a structure that can be variably adjusted to a direction and a gradient (tilt angle) suitable for the altitude of the sun at the installation location of the data acquisition device 13-1. As the photovoltaic power generation panel 23, a plate-like one using a single crystal or polycrystalline silicon type, or a sheet-like or film-like one using a thin film silicon type can be appropriately employed.

  The storage battery 25 has a function of supplying direct-current power to each unit including the radiation dose measurement unit 17, the satellite communication unit 19, the GPS receiver 21, the storage unit 27, and the control unit 29. As the storage battery 25, a fully charged battery is used. However, the capacity of the storage battery 25 decreases according to the use frequency and use time (including spontaneous discharge).

  Therefore, in order to suppress the decrease rate of the capacity of the storage battery 25 (adjust the charge / discharge balance), the storage battery 25 is configured to be charged using the power generated by the solar power generation panel 23. Although the capacity | capacitance of the storage battery 25 is not specifically limited, For example, even if the charge by solar power generation interrupts about several weeks, it can set to the capacity | capacitance which can maintain the operation state of the data acquisition apparatus 13-1.

  The storage unit 27 has a function of storing the radiation dose data measured by the radiation dose measurement unit 17 and identification information unique to the data acquisition device 13-1. The identification information unique to the data acquisition device 13-1 is used in the data management device 15 when managing the radiation dose data in association with the location of the data acquisition device 13 that acquired the radiation dose data.

  The control unit 29 maintains a standby state in which power can be saved in normal times. However, when receiving a wake-up trigger signal to be described later from the data management device 15 via the satellite communication unit 19, the control unit 29 changes its operation state from the standby state to the radiation dose measurement unit 17, the satellite communication unit. 19, It works so that the operation | movement of each part containing the GPS receiver 21 and the memory | storage part 27 may be shifted to the controllable operating state. In this operating state, the control unit 29 manages radiation dose data and identification information unique to the data acquisition device 13-1 (including current position data based on GPS information) through the satellite communication line 31 by the satellite communication unit 19. Control to send to the device 15 is performed.

  The control unit 29 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), an input / output circuit (including an A / D converter and a D / A converter), and the like. Configured. The CPU operates according to the program stored in the ROM so as to realize the functions of the control unit 29 using the RAM as a work area.

  On the other hand, as shown in FIG. 1A, the data management device 15 includes a satellite communication unit 33, a radiation dose database (hereinafter abbreviated as “radiation dose DB”) 35, and a management unit 37. . FIG. 1C is a two-dimensional table showing an example of the radiation dose DB 35 included in the data management device 15 which is a component of the radiation dose data management system 11 according to the embodiment of the present invention.

  The satellite communication unit 33 corresponding to the management-side communication unit of the present invention has a function of performing communication with the data acquisition device 13 serving as a communication partner using the satellite communication line 31 via the artificial satellite.

  As shown in FIG. 1C, the radiation dose DB 35 includes identification information, measurement date and time, current position data, measurement height (cm), measurement value (μSv / h), and remarks as items in the column direction. . The identification information is unique information assigned to each of the plurality of data acquisition devices 13. In the example of FIG. 1C, codes “13-1” and “13-2” of the data acquisition device are described as identification information. The measurement date and time is information on the date and time when the radiation dose was measured. The current position data is information representing the radiation dose measurement location. In the example of FIG. 1C, latitude and longitude are described as current position data. The measurement height (cm) is information indicating the height position where the radiation dosimeter 17 is installed. In the example of FIG. 1C, the height position (5 cm / 50 cm / 100 cm) with respect to the ground surface is described as the measurement height (cm). The measurement value (μSv / h) is information obtained by converting an actual measurement result related to the radiation dose into a numerical value (equivalent dose) serving as an index representing the magnitude of the influence on the human body. In the example of FIG. 1C, the name of the place corresponding to the current position data is described in the remarks column.

  The management unit 37 has a function of managing the plurality of data acquisition devices 13 in an integrated manner. Specifically, the management unit 37 causes the satellite communication unit 33 to generate a wake-up trigger signal for shifting the operation state of the data acquisition device 13 from the standby state to the operation state according to a preset time schedule (timetable). Data based on a function to be transmitted to the data acquisition device 13 set in advance through the satellite communication line 31, radiation dose data transmitted from the plurality of data acquisition devices 13, identification information, the state of charge of the storage battery 25, and GPS information Sleep-down trigger for shifting the operating state of the data acquisition device 13 from the operating state to the standby state in accordance with a function for receiving the current position data of the acquisition device 13 by the management-side communication unit 33 and a preset time schedule (timetable) The signal is preset by the satellite communication unit 33 through the satellite communication line 31. Function to transmit the obtained device 13, and has a function of a time transition of the radiation dose data obtained from a plurality of data acquisition device 13, managed in association with each data acquisition device 13. The radiation dose DB 35 and the management unit 37 correspond to the “management unit” of the present invention.

  The management unit 37 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), an input / output circuit (including an A / D converter and a D / A converter), and the like. Configured. The CPU operates according to a program stored in the ROM so as to realize the functions of the management unit 37 using the RAM as a work area.

[Operation of Radiation Dose Data Management System 11 According to Embodiment of the Present Invention]
Next, the operation of the radiation dose data management system 11 according to the embodiment of the present invention (corresponding to the “radiation dose data communication method” of the present invention) will be described with reference to FIG. FIG. 2 is a process diagram showing the flow of processing between the data acquisition device 13 and the data management device 15 constituting the data management system 11 according to the embodiment of the present invention. 2 includes a plurality of data acquisition devices 13-1, 13-2,... According to a preset time schedule (timetable). Of 13-n, it is performed between the data acquisition device 13 and the data management device 15 set in advance as the radiation dose data acquisition target. In the example illustrated in FIG. 2, the description will be made assuming that the setting for acquiring and managing radiation dose data is performed between the data acquisition device 13-1 and the data management device 15.

  In step S11 shown in FIG. 2, the management unit 37 of the data management device 15 wakes up a trigger signal (specific to the data acquisition device 13-1) that shifts the operation state of the data acquisition device 13-1 from the standby state to the operation state. (Including identification information) is transmitted to the data acquisition apparatus 13-1 through the satellite communication line 31 by the satellite communication unit 33.

  In step S12, when the wakeup trigger signal is received via the satellite communication unit 19, the control unit 29 of the data acquisition device 13-1 determines whether or not the wakeup trigger signal is addressed to itself. Verification is performed based on identification information included in the signal. As a result of this collation, when it is determined that the wakeup trigger signal is destined for itself, the control unit 29 of the data acquisition device 13-1 shifts its operation state from the standby state to the operation state. Let In this operating state, the control unit 29 wakes up an answer including the fact that its own operating state is in the operating state and identification information unique to the data acquisition device 13-1 (including current position data based on GPS information). The signal is sent back to the data management apparatus 15 through the satellite communication line 31 by the satellite communication unit 19.

  In step S13, when a wakeup answer signal is received via the satellite communication unit 33, the management unit 37 of the data management device 15 includes whether or not the wakeup answer signal is valid in the wakeup answer signal. Collation based on identification information. When it is determined that the wake-up answer signal is valid as a result of this collation, the management unit 37 of the data management device 15 sends a data request with measurement conditions to the satellite communication unit 33 through the satellite communication line 31. It is transmitted to the data acquisition device 13-1. As a data request with measurement conditions, for example, radiation doses related to measured values (equivalent doses) at three kinds of height positions (5 cm / 50 cm / 100 cm) based on the ground surface can be employed. Moreover, you may set measurement time and the return time of the measured radiation dose data as measurement conditions.

  In step S14, when a data request with measurement conditions is received via the satellite communication unit 19, the control unit 29 of the data acquisition device 13-1 receives the three types of height positions (5 cm / 50 cm / 100 cm) that have received the request. The radiation dose data related to the measured value (equivalent dose) of the radiation dose is returned to the data management device 15 through the satellite communication line 31 by the satellite communication unit 19.

  In step S15, when the request data is returned via the satellite communication unit 33, the management unit 37 of the data management device 15 causes the sleep state trigger signal to shift the operation state of the data acquisition device 13 from the operation state to the standby state. Is transmitted to the preset data acquisition device 13-1 through the satellite communication line 31 by the satellite communication unit 33.

  In step S <b> 16, when the sleep down trigger signal is received via the satellite communication unit 19, the control unit 29 of the data acquisition device 13-1 shifts its operation state from the operation state to the standby state. In this standby state, the control unit 29 has a sleep down answer including its own operation state in the standby state and identification information (including current position data based on GPS information) unique to the data acquisition device 13-1. The signal is sent back to the data management apparatus 15 through the satellite communication line 31 by the satellite communication unit 19.

When the reply of the sleep down answer signal is received via the satellite communication unit 33, the management unit 37 of the data management device 15 ends a series of processing steps related to acquisition of radiation dose data.
In addition, when there are a plurality of data acquisition devices 13 from which radiation dose data is acquired, the processing steps of steps S11 to S16 are broadcasted by the number of data acquisition devices 13 from which radiation dose data is acquired. Or, it is performed by repeating sequentially.

[Operational Effects of Radiation Dose Data Management System 11 According to Embodiment of the Present Invention]
Next, the effect of the radiation dose data management system 11 according to the embodiment of the present invention will be described.

  The radiation dose data management system 11 according to the embodiment of the present invention includes a data acquisition device 13 that acquires radiation dose data, and a data management device 15 that manages a time transition of the radiation dose data acquired by the data acquisition device 13. Prepare.

  The data acquisition device 13 includes a radiation dose measurement unit 17 that measures radiation dose data, a storage unit 27 that stores radiation dose data and identification information unique to the data acquisition device 13, and a radiation dose data stored in the storage unit 27. And the satellite communication unit 19 that transmits the identification information to the data management device 15, the control unit 29 that controls the operation of each unit including the radiation dose measurement unit 17, the storage unit 27, and the satellite communication unit 19, and the control unit 29 And a storage battery 25 that supplies power for performing the operation to the components.

  The data management device 15 uses the radiation dose DB 35 to receive the radiation dose data and identification information received by the satellite communication unit 33 and the satellite communication unit 33 that receives the radiation dose data and identification information transmitted from the satellite communication unit 19. And a management unit 37 that manages the data acquisition device 13 in association with each other.

  According to the radiation dose data management system 11 according to the embodiment of the present invention, since the storage battery 25 that supplies power for causing the control unit 29 to perform a predetermined operation is provided, for example, in a combined disaster caused by an earthquake and a tsunami Even when a power failure occurs, radiation dose data acquisition and management can be performed reliably.

  The spatial radiation dose, which is the monitoring target data according to the embodiment of the present invention, varies from moment to moment according to the release amount, concentration, distance from the release source, wind direction, and the like of the radioactive material in the atmosphere. However, radiation cannot be felt directly on the human body. For this reason, when measuring a radiation dose manually, the influence regarding the radiation exposure of the measurer at the time of a measurement becomes a problem.

  In this regard, in the radiation dose data management system 11 according to the embodiment of the present invention, the data acquisition devices 13 are distributed and installed outdoors. The data management device 15 is installed in, for example, an indoor facility or a vehicle cabin of a local government. Then, acquisition and management of radiation dose data via the satellite communication medium are performed between the data acquisition device 13 and the data management device 15.

  Therefore, according to the radiation dose data management system 11 according to the embodiment of the present invention, instead of the measurement of the radiation dose through the manual operation, the radiation is obtained by the communication without the manual operation from the data acquisition device 13 installed in an appropriate remote place. Since the dose data can be acquired, the influence on the human body due to the radiation when measuring the radiation dose can be eliminated. In addition, the number of personnel, time and cost for measuring radiation dose can be greatly reduced. Furthermore, since the radiation dose data is communicated using the satellite communication medium, a secondary effect that the satellite communication medium is resistant to disaster can be expected in the sense that the satellite communication medium has high availability when the disaster occurs.

  In particular, according to the radiation dose data management system 11 according to the embodiment of the present invention, when the data acquisition device 13 is installed in a remote area or a radiation-contaminated area where it is difficult for people to enter, such a remote area or a radiation-contaminated area Since radiation dose data can be acquired and managed, it has an excellent effect that a hot spot is not missed.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, the control unit 29 of the data acquisition device 13 stores the radiation dose data and the identification information according to a preset time schedule (timetable) (on time). A configuration in which the satellite communication unit 19 performs control to be transmitted to the data management device 15 may be adopted.

  As described above, if a configuration in which a time schedule (timetable) for performing acquisition and communication of radiation dose data is set in advance on the data acquisition device 13 side is adopted, the data management device 15 side will have the data acquisition device 13 on the side. The system configuration can be simplified because it is sufficient to perform data management after waiting for reception of radiation dose data transmitted from.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, the management units 35 and 37 of the data management device 15 change the operation state of the control unit 29 of the data acquisition device 13 from the standby state where power saving is possible. The satellite communication unit 33 transmits a wakeup trigger signal for shifting the operation to the controllable operating state to the data acquisition device 13. On the other hand, when receiving the wake-up trigger signal via the satellite communication unit 19, the control unit 29 of the data acquisition device 13 that normally maintains the standby state shifts its operation state from the standby state to the operation state. In addition, in this operating state, a configuration is adopted in which the radiation dose data and the identification information are controlled to be transmitted to the data management device 15 by the satellite communication unit 19.

  As described above, if the configuration in which the data acquisition device 13 side transmits the radiation dose data in response to the wake-up trigger signal from the data management device 15 side, the requirement set on the data management device 15 side is adopted. Since radiation dose data can be collected at the timing, radiation dose data can be acquired and managed flexibly.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, when receiving the wake-up trigger signal via the satellite communication unit 19, the control unit 29 of the data acquisition device 13-1 changes its operation state, While shifting from the standby state to the operating state, at the time of this operating state, the operation state of the control unit 29 itself is in the operating state and identification information unique to the data acquisition device 13-1 (current position data based on GPS information) In this configuration, the satellite communication unit 19 returns a wake-up answer signal to the data management device 15 through the satellite communication line 31.

  In this way, if the data acquisition device 13 side adopts a configuration in which the wakeup answer signal is returned in response to the wakeup trigger signal from the data management device 15 side, the data management device 15 side receives the data It is possible to reliably collect and manage radiation dose data while confirming the operating state of the management device 15.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, when the wake-up answer signal is received via the satellite communication unit 33, the management unit 37 of the data management device 15 requests the data request with the measurement condition. Is transmitted to the data acquisition device 13-1 through the satellite communication line 31 by the satellite communication unit 33.

  As described above, if the data management device 15 side adopts a configuration in which a data request with a measurement condition is transmitted in response to the wake-up answer signal from the data acquisition device 13 side, the data acquisition device 13 side The data request with the measurement condition can be reliably processed by maintaining the operation state of the control unit 29 in the operating state. Further, since the data management device 15 can collect the radiation dose data according to the data request with the measurement conditions set on the device 15 side, the acquisition and management of the radiation dose data can be performed flexibly and reliably. it can.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, as a data request with measurement conditions, measured values (equivalent doses) of three kinds of height positions (5 cm / 50 cm / 100 cm) based on the ground surface are used. ) Will be adopted. In addition, when a data request with measurement conditions is received via the satellite communication unit 19, the control unit 29 of the data acquisition device 13-1 receives radiation at the three types of height positions (5 cm / 50 cm / 100 cm) that have received the request. A configuration is adopted in which the dose is measured and the dose data related to the measured value (equivalent dose) of the dose is returned by the satellite communication unit 19 to the data management device 15 through the satellite communication line 31.

  If comprised in this way, the data management apparatus 15 will be the radiation dose data (refer the table of FIG. 1C) regarding the measured value (equivalent dose) of three types of height positions (5 cm / 50 cm / 100 cm) on the basis of the ground surface. ) Can be collected, so that radiation dose data relating to different height positions can be compared at one measurement point, or a common height position (for example, 100 cm) between different measurement points. The analysis work based on the collected radiation dose data can be performed in a multifaceted manner, such as comparing the radiation dose data related to (1).

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, when the response of the request data is received via the satellite communication unit 33, the management unit 37 of the data management device 15 changes the operation state of the data acquisition device 13. A configuration is adopted in which a sleep down trigger signal for shifting from the operating state to the standby state is transmitted by the satellite communication unit 33 through the satellite communication line 31 to the preset data acquisition device 13-1.

  Furthermore, in the radiation dose data management system 11 according to the embodiment of the present invention, when the sleep down trigger signal is received via the satellite communication unit 19, the control unit 29 of the data acquisition device 13-1 While shifting from the operating state to the standby state, at the time of this standby state, the operation state of the control unit 29 itself is in the standby state, and identification information unique to the data acquisition device 13-1 (current position data based on GPS information) In other words, the satellite communication unit 19 returns a response to the data management device 15 through the satellite communication line 31.

  If comprised in this way, the effect of reducing the average power consumption of the data acquisition device 13 can be expected. Here, the average power consumption reduction effect of the data acquisition device 13 will be described with reference to FIG. FIG. 3 is a diagram illustrating the time transition of the power consumption according to the displacement of the operation state of the data acquisition device 13. T1 and T3 illustrated in FIG. 3 represent sections in which the operation state of the data acquisition device 13 is in a standby state. T2 shown in the figure represents a section in which the operation state of the data acquisition device 13 is in the operating state. “Tup” shown in the figure represents the time when the wakeup trigger signal is received. Tdn shown in the figure represents the time when the sleep down trigger signal is received. P1 shown in the figure represents the power consumption when the operation state of the data acquisition device 13 is in the standby state. P2 shown in the figure represents the power consumption when the operation state of the data acquisition device 13 is in the operating state.

  As shown in FIG. 3, the data acquisition device 13 receives the wake-up trigger signal transmitted from the data management device 15 side, and changes the operation state of the control unit 29 from the standby state to the operation state at the reception time tup. To migrate. Along with this, the power consumption of the data acquisition device 13 increases from P1 to P2. The data acquisition device 13 acquires and communicates radiation dose data in the section T2 in which the operation state of the control unit 29 is in the operating state.

  Next, as shown in FIG. 3, the data acquisition device 13 receives the sleep down trigger signal transmitted from the data management device 15 side, and changes the operation state of the control unit 29 from the operation state at the reception time tdn. Move to standby state. Along with this, the power consumption of the data acquisition device 13 decreases from P2 to P1. The data acquisition device 13 waits for a wakeup trigger signal to be transmitted from the data management device 15 side in the sections T1 and T3 in which the operation state of the control unit 29 is in the standby state. In short, in the sections T1 and T3, the data acquisition device 13 does not acquire and communicate radiation dose data.

  For this reason, in the sections T1 and T3 in which the operation state of the control unit 29 is in the standby state, the power consumption can be suppressed lower than in the section T2 in which the operation state of the control unit 29 is in the operating state. Therefore, according to the radiation dose data management system 11 according to the embodiment of the present invention, the effect of reducing the average power consumption of the data acquisition device 13 can be expected.

  Moreover, in the radiation dose data management system 11 which concerns on embodiment of this invention, it further has the solar power generation part 23 which has the solar power generation panel 23, and performs solar power generation, and the storage battery 25 is the taiko power generation part 23. A configuration is adopted in which charging is performed using the generated power.

  If comprised in this way, in the area T1 and T3 (refer FIG. 3) in which the operation state of the control part 29 is a standby state, the solar power generation part 23 will charge the storage battery 25 by solar power generation. Further, in the section T <b> 2 (see FIG. 3) in which the operation state of the control unit 29 is in the operating state, the storage battery 25 supplies power to each unit including the control unit 29. Therefore, according to the radiation dose data management system 11 according to the embodiment of the present invention, by self-suppliing the power consumption on the data acquisition device 13 side, for example, in forests, seas, radiation-contaminated areas where power supply is difficult, etc. Even when the data acquisition device 13 is installed, acquisition and communication of radiation dose data can be performed over a long period of time.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, the control unit 29 of the data acquisition device 13 further has a function of detecting the state of charge of the storage battery 25, and includes radiation dose data, identification information, and You may employ | adopt the structure which performs control which transmits the charge condition of the storage battery 25 to the data management apparatus 15 by the satellite communication part 19. FIG.

  If comprised in this way, since the data management apparatus 15 side can grasp | ascertain the charge condition of the storage battery 25 in addition to acquisition and management of radiation dose data, the storage battery 25 of a certain data acquisition apparatus 13 is maintained. As necessary, the state of the storage battery 25 included in the data acquisition device 13 can be appropriately managed in an integrated manner.

  Further, in the radiation dose data management system 11 according to the embodiment of the present invention, the control unit 29 of the data acquisition device 13 replaces or in addition to the state of charge of the storage battery 25 with the state of the data acquisition device 13 (for example, Whether the radiation dose measuring unit 17, the satellite communication unit 19, the GPS receiver 21, the solar power generation panel 23, the storage battery 25, the storage unit 27, or the control unit 29 is functioning normally is determined according to the self-diagnosis program. The configuration may be adopted in which the satellite communication unit 19 performs control to transmit to the data management device 15.

  If comprised in this way, since the data management apparatus 15 side can grasp | ascertain whether the state of the data acquisition apparatus 13 side is normal in addition to acquisition and management of radiation dose data, a certain data acquisition The device 13 can appropriately manage the state of the data acquisition device 13 such that maintenance is required. In addition, when it is determined that an abnormality has occurred in a certain function unit in response to the state of the data acquisition device 13 relating to whether the function of each unit is normal or not, by performing maintenance on the function unit, It is also possible to expect the effect of simplifying the maintenance management of the functional part (the cost reduction effect associated therewith). Furthermore, on the data management device 15 side, when the data acquisition device 13 acquires or determines that the data acquisition device 13 is in an abnormal state, a configuration may be adopted in which an operation for stopping acquisition of radiation dose data is performed.

  In the radiation dose data management system 11 according to the embodiment of the present invention, the control unit 29 of the data acquisition device 13 further has a function of detecting the current position of the data acquisition device 13 based on the GPS information, and the radiation dose Adopting a configuration for controlling the satellite communication unit 19 to transmit the current position data of the data acquisition device 13 based on the data, identification information, the storage battery 25, and the GPS information to the data management device 15 Also good.

  If comprised in this way, on the data management device 15 side, the radiation dose data, the identification information, and the state of charge of the storage battery 25 are managed in association with the current position data of the corresponding data acquisition device 13 (for example, on a map). Radiation dose data can be mapped to the radiation dose data, and the radiation dose data can be managed more appropriately.

  In the radiation dose data management system 11 according to the embodiment of the present invention, the radiation dose measurement unit 17 of the data acquisition device 13 includes a plurality of radiation dosimeters 17a, 17b, and 17c. 17b and 17c adopt a configuration in which they are provided at mutually different height positions on the basis of the ground surface (when the data acquisition device 13 is provided on the sea, it is read as “the sea surface”).

  If comprised in this way, the data management apparatus 15 will carry out the radiation dose data which concern on several radiation dosimeters 17a, 17b, 17c each provided in mutually different height positions on the basis of the ground surface (refer the table of FIG. 1C). Because of this, radiation dose data related to different height positions at one measurement point can be compared, or radiation doses related to a common height position can be compared between different measurement points. Analysis work based on collected radiation dose data, such as comparing data, can be performed in a multifaceted manner.

  In addition, in the radiation dose data management system 11 according to the embodiment of the present invention, a data acquisition device 13 that acquires radiation dose data, a data management device 15 that manages temporal transition of radiation dose data acquired by the data acquisition device 13, and The radiation dose data communication method described below is adopted when communicating the radiation dose data between the two.

  In this radiation dose data communication method, the management unit 37 of the data management device 15 sends a wake-up trigger signal for shifting the operation state of the data acquisition device 13 from the standby state to the operation state by the satellite communication unit 33 to the data acquisition device 13. When the control unit 29 of the data acquisition device 13 receives the wake-up trigger signal via the satellite communication unit 19, the operation state of the control unit 29 itself is shifted from the standby state to the operating state. A step of returning to the data management device 15 a wake-up answer signal including the identification information unique to the data acquisition device 13 and the fact that the operation status of the control unit 29 itself is in the operation state in this operation state; When the management unit 37 of the data management device 15 receives the reply of the wake-up answer signal via the satellite communication unit 33, the measurement condition When the satellite communication unit 33 transmits a data request to the data acquisition device 13 and the control unit 29 of the data acquisition device 13 receives a data request with a measurement condition via the satellite communication unit 19. And the step of returning the radiation dose data related to the measured value of the radiation dose to the data management device 15 by the satellite communication unit 19 is adopted. .

  According to the radiation dose data communication method according to the embodiment of the present invention, the data management device 15 can perform acquisition and management of radiation dose data while remotely managing the operation state of the data acquisition device 13 remotely. it can. Moreover, the effect of reducing the average power consumption of the data acquisition device 13 can be expected.

[Other Embodiments]
The embodiment of the present invention described above shows an embodiment of the present invention. Therefore, the technical scope of the present invention should not be limitedly interpreted by these. This is because the present invention can be implemented in various forms without departing from the gist or main features thereof.

  For example, in the description according to the embodiment of the present invention, the satellite communication line is exemplified as the communication medium when performing data communication between the data acquisition device 13 and the data management device 15, but the present invention is not limited to this. It is not limited to examples. As the communication medium, for example, a cellular phone network or a public phone network may be used.

  In the description according to the embodiment of the present invention, the data acquisition device 13 side transmits the current position data of the data acquisition device 13 based on the GPS information in addition to the radiation dose data and the identification information by the satellite communication unit 19. Although the configuration for transmitting to the data management apparatus 15 has been described as an example, the present invention is not limited to this example. The current position data of the data acquisition device 13 based on the GPS information can be omitted. In this case, it is assumed that the data management device 15 side has a relation table describing the installation location information of the data acquisition device 13 in association with identification information unique to the data acquisition device 13. Thereby, the data management device 15 side can manage the installation location of the data acquisition device 13 and the radiation dose data related to the data acquisition device 13 in a one-to-one relationship by referring to the relationship table. .

  Further, in the description according to the embodiment of the present invention, the data acquisition device 13 has been described with an example in which it is installed outdoors such as an area where a radiation dose is assumed to be high, a teaching area, a residential area, a mountainous area, or the sea. However, the present invention is not limited to this example. A configuration may be adopted in which the data acquisition device 13 is mounted on an automobile and a mobile radiation dose monitoring vehicle is used by using an in-vehicle storage battery as a substitute for the storage battery 25. Furthermore, the data acquisition device 13 is mounted on a train, a ship, or an airplane instead of the automobile, and as a substitute for the storage battery 25, a storage battery mounted on the train, ship, or airplane is used. You may employ | adopt the structure used as a mobile radiation dose monitoring mobile body.

  Further, in the description according to the embodiment of the present invention, in response to the sleep down trigger signal transmitted from the data management device 15 side, the data acquisition device 13 shifts the operation state from the operation state to the standby state. Although an example has been described, the present invention is not limited to this example. The data acquisition device 13 changes its operation state immediately after returning the request data from the data management device 15 side or after returning the request data from the data management device 15 side after a predetermined time has elapsed. You may comprise so that it may transfer to a standby state from an operation state. In this case, the sleep down trigger signal transmitted from the data management device 15 side and the sleep down answer signal returned from the data acquisition device 13 side can be omitted.

  In the embodiment of the present invention, the data acquisition device 13 digitizes the radiation dose data measured by the radiation dose measurement unit 17 and transmits the digitized data to the data management device 15, thereby improving the efficiency of the tabulation work related to the radiation dose data. A configuration for achieving the above may be employed.

  In the embodiment of the present invention, the data management device 15 accumulates the radiation dose data transmitted from the plurality of data acquisition devices 13, thereby associating and displaying the spot on the map and the spatial radiation dose. A radiation dose map can be created. The space radiation dose map created in this way can be shared to the public via the network (World Wide Web), so that it is possible to share space radiation dose information with high public interest.

  Further, in the description according to the embodiment of the present invention, an example in which the storage battery 25 is charged by photovoltaic power generation has been described in order to suppress the speed at which the capacity of the storage battery 25 decreases (adjustment of charge / discharge balance). The present invention is not limited to this example. As the storage battery 25, for example, a battery having a capacity capable of maintaining the function of the radiation dose data management system 11 through a predetermined monitoring period such as one year may be adopted. In this case, the power generation facility for charging the storage battery 25 can be omitted.

  Finally, in the description according to the embodiment of the present invention, solar power generation is illustrated as an example of the power generation facility for charging the storage battery 25, but the present invention is not limited to this example. As the power generation facility for charging the storage battery 25, for example, a power generation facility such as wind power generation may be employed.

11 Radiation dose data management system (data management system)
13-1, 13-2, ..., 13-n Multiple data acquisition devices 15 Data management device 17 Radiation dose measurement unit 19 Satellite communication unit (acquisition side communication unit)
21 GPS receiver 23 Solar power generation panel (solar power generation unit)
25 Storage Battery 27 Storage Unit 29 Control Unit 31 Satellite Communication Line 33 Satellite Communication Unit (Management Communication Unit)
35 Radiation dose DB (Management Department)
37 Management Department

Claims (9)

A data acquisition device for acquiring monitoring target data, and a data management device for managing the time transition of the monitoring target data acquired by the data acquisition device,
The data acquisition device includes:
A measurement unit for measuring monitoring target data;
A storage unit for storing monitoring target data measured by the measurement unit and identification information unique to the data acquisition device;
An acquisition-side communication unit that transmits the monitoring target data and the identification information stored in the storage unit to the data management device;
A control unit that controls the operation of each unit including the measurement unit, the storage unit, and the acquisition-side communication unit;
A storage battery for supplying power to the control unit to perform the operation;
With
The data management device includes:
A management communication unit that receives the monitoring target data and the identification information transmitted from the acquisition communication unit;
A management unit that manages the monitoring target data and the identification information received via the management communication unit 33 in association with the data acquisition device;
A data management system comprising: A data acquisition device for acquiring radiation dose data, and a data management device for managing the time transition of the radiation dose data acquired by the data acquisition device,
The data acquisition device includes:
A radiation dose measurement unit for measuring radiation dose data;
A storage unit for storing radiation dose data measured by the radiation dose measurement unit and identification information unique to the data acquisition device;
An acquisition-side communication unit that transmits the radiation dose data and the identification information stored in the storage unit to the data management device;
A control unit that controls the operation of each unit including the radiation dose measurement unit, the storage unit, and the acquisition-side communication unit;
A storage battery for supplying power to the control unit to perform the operation;
With
The data management device includes:
A management communication unit that receives the radiation dose data and the identification information transmitted from the acquisition communication unit;
A management unit that manages the radiation dose data and the identification information received via the management-side communication unit 33 in association with the data acquisition device;
A radiation dose data management system comprising: The radiation dose data management system according to claim 2,
The control unit of the data acquisition device performs control to transmit the radiation dose data and the identification information to the data management device by the acquisition side communication unit according to a preset schedule.
Radiation dose data management system characterized by that. The radiation dose data management system according to claim 2,
The management unit of the data management device manages the wakeup trigger signal that shifts the operation state of the control unit of the data acquisition device from a standby state where power can be saved to an operation state where the operation of each unit can be controlled. While performing control to be transmitted to the data acquisition device by the side communication unit,
When the control unit of the data acquisition device that normally maintains the standby state receives the wake-up trigger signal via the acquisition-side communication unit, the control unit changes its operation state from the standby state to the operation state. And in the operation state, the radiation dose data and the identification information are transmitted to the data management device by the acquisition side communication unit.
Radiation dose data management system characterized by that. The radiation dose data management system according to claim 2,
A solar power generation unit that has a solar power generation panel and performs solar power generation,
The storage battery is charged using the power generated by the solar power generation unit,
Radiation dose data management system characterized by that. The radiation dose data management system according to claim 5,
The control unit of the data acquisition device further has a function of detecting a state of charge of the storage battery, and the acquisition side communication unit displays the radiation dose data, the identification information, and the state of charge of the storage battery. Control to send to the management device,
Radiation dose data management system characterized by that. The radiation dose data management system according to claim 6,
The control unit of the data acquisition device further has a function of detecting the current position of the data acquisition device based on GPS information, and includes the radiation dose data, the identification information, the state of charge of the storage battery, and the GPS information. Based on the current position data of the data acquisition device based on the acquisition side communication unit to control the transmission to the data management device,
Radiation dose data management system characterized by that. The radiation dose data management system according to claim 2,
The radiation dose measuring unit of the data acquisition device has a plurality of radiation dosimeters,
The plurality of radiation dosimeters are respectively provided at different height positions with respect to the ground surface.
Radiation dose data management system characterized by that. Used when communicating radiation dose data between a data acquisition device that acquires radiation dose data and a data management device that manages the time transition of the radiation dose data acquired by the data acquisition device,
The management unit of the data management device transmits a wake-up trigger signal for shifting the operation state of the data acquisition device from a standby state to an operation state to the data acquisition device by a management-side communication unit;
When the control unit of the data acquisition device receives the wake-up trigger signal via the acquisition-side communication unit, the control unit itself moves the operation state from the standby state to the operation state, and at the time of this operation state And a step of returning a wake-up answer signal including identification information unique to the data acquisition device to the data management device, indicating that the operation state of the control unit itself is in an operating state;
When the management unit of the data management device receives the reply of the wake-up answer signal via the management-side communication unit, the management-side communication unit transmits a data request with a measurement condition to the data acquisition device. A process of
When the control unit of the data acquisition device receives a data request with a measurement condition via the acquisition side communication unit, it measures the radiation dose according to the received measurement condition and the radiation related to the measurement value of the radiation dose Returning the amount data to the data management device by the acquisition-side communication unit;
A radiation dose data communication method comprising:

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